An apparatus to dispense fluids may include a reusable portion and a disposable portion. The disposable portion may include components that come into contact with the fluid, while the reusable portion may include only components that do not come into contact with the fluid. The apparatus includes an
An apparatus to dispense fluids may include a reusable portion and a disposable portion. The disposable portion may include components that come into contact with the fluid, while the reusable portion may include only components that do not come into contact with the fluid. The apparatus includes an acoustic volume sensor that acoustically excites a fixed-volume chamber and a measurement chamber with a loudspeaker and measures the acoustic response with microphones acoustically coupled to the fixed volume chamber and the measurement chamber. The loudspeaker and sensing microphones are connected to the measurement chamber by separate ports. A detachable dispensing chamber is coupled to the acoustic volume sensor. The volume of the fluid dispensed is determined by a processor based on the acoustic response of the microphones to acoustic excitement by the loudspeaker.
대표청구항▼
1. An apparatus to dispense fluid comprising: a first portion containing a substrate having flexible membrane material thereon and incorporating therein: a fluid path from a reservoir port to a cannula;at least one valve covered by a valve portion of the flexible membrane material;at least one pump
1. An apparatus to dispense fluid comprising: a first portion containing a substrate having flexible membrane material thereon and incorporating therein: a fluid path from a reservoir port to a cannula;at least one valve covered by a valve portion of the flexible membrane material;at least one pump covered by a pump portion of the flexible membrane material; anda dispensing chamber, the dispensing chamber containing a variable fluid volume and covered by a dispensing chamber portion of the flexible membrane material, wherein the dispensing chamber portion of the flexible membrane is a different material from one of the valve portion and the pump portion of the flexible membrane material;a second portion comprising: a mechanical assembly that interacts mechanically with the pump portion and valve portion of the flexible membrane material in such a manner as to achieve pumping of fluid along the fluid path; andan acoustic volume sensor assembly to measure the change in fluid volume of the dispensing chamber, the acoustic volume sensor assembly comprising: a structure containing a fixed-volume chamber, a first port, a measurement chamber, and a second port, the structure is located within the apparatus so that the dispensing chamber and measurement chamber share a boundary defined by the dispensing chamber portion of the flexible membrane material, the first port acoustically couples the fixed-volume chamber to the measurement chamber;a printed circuit board disposed within the structure, the printed circuit board including: a loudspeaker, the loudspeaker generating pressure waves in the fixed-volume chamber;a reference microphone, the reference microphone producing a reference signal; a sensing microphone acoustically coupled to the measurement chamber via a second port, the sensing microphone producing a sensing signal in response to the pressure waves that travel through the first port, the measuring chamber and the second port before reaching the sensing microphone; anda processor configured to calculate a change in volume of the measurement chamber wherein the processor determines the volume of fluid displaced from the dispensing chamber. 2. The apparatus to dispense fluid according to claim 1 wherein the sensing microphone and loudspeaker are located to prevent the loudspeaker pressure waves from impacting the sensing microphone without passing through the measurement chamber. 3. The apparatus to dispense fluid according to claim 1 further comprising a flared aperture on at least one of the first and second ports, wherein the flared aperture is proximal to the measurement chamber. 4. The apparatus to dispense fluid according to claim 1 further comprising a dispensing spring, wherein the dispensing spring provides additional resilience to the a dispensing chamber portion of the flexible membrane material. 5. The apparatus to dispense fluid according to claim 4 wherein the dispensing spring is part of the acoustic volume sensor. 6. An apparatus to dispense fluid comprising: a first portion containing a substrate having flexible membrane material thereon and incorporating a fluid path that fluidically connects: a reservoir;at least one valve covered by a valve portion of the flexible membrane material;at least one pump covered by a pump portion of the flexible membrane material;and a dispensing chamber, the dispensing chamber containing a variable fluid volume and covered by a dispensing chamber portion of the flexible membrane material;a second portion comprising: a mechanical assembly that interacts mechanically with the pump portion and valve portion of the flexible membrane material in such a manner as to achieve pumping of fluid along the fluid path; andan acoustic volume sensor to measure the change in fluid volume of the dispensing chamber, the acoustic volume sensor comprising: a structure containing a fixed-volume chamber, a first port, a measurement chamber and a second port, wherein the structure is located within the apparatus so that the dispensing chamber and measurement chamber share a boundary defined by the dispensing chamber portion of the flexible membrane material, wherein the first port acoustically couples the fixed volume chamber to the measurement chamber to form an acoustically contiguous region;a printed circuit board disposed within the structure, the printed circuit board including a loudspeaker and a sensing microphone, wherein the loudspeaker and sensing microphone are acoustically coupled to the measurement chamber via the first port and the second port respectively, wherein the pressure waves generated by the loudspeaker in fixed-volume chamber subsequently pass through the first port, the measuring chamber and then the second port before reaching the sensing microphone, the sensing microphone produces a first signal based on the response of the measurement chamber to excitement by the loudspeaker; anda processor in communication with the loudspeaker and the sensing microphone, the processor receiving a first signal at a first instance, the processor receiving the first signal at a second instance, and the processor determining a change in an acoustic characteristic of the measurement chamber associated with the first signal at the first instance and the first signal at the second instance, the processor is configured to calculate a change in volume of the measurement chamber associated with a change in an acoustic characteristic of the measurement chamber, wherein the processor determines a volume of fluid displaced from the dispensing chamber associated with the change in the volume of the measurement chamber. 7. The apparatus to dispense fluid according to claim 6 further comprising a flared aperture on at least one of the first and second ports, wherein the flared aperture is proximal to the measurement chamber. 8. The apparatus to dispense fluid according to claim 6 further comprising a dispensing spring, wherein the dispensing spring provides additional resilience to the a dispensing chamber portion of the flexible membrane material. 9. The apparatus to dispense fluid according to claim 8 wherein the dispensing spring is part of the acoustic volume sensor. 10. An apparatus to dispense fluid comprising: a first portion containing a substrate having flexible membrane material thereon and incorporating therein: a fluid path from a reservoir port to a cannulaat least one valve covered by a valve portion of the flexible membrane material;at least one pump covered by a pump portion of the flexible membrane material;and a dispensing chamber, the dispensing chamber containing a variable fluid volume and covered by a dispensing chamber portion of the flexible membrane material, wherein the dispensing chamber portion of the flexible membrane material is a different material from one of the valve portion and the pump portion of the flexible membrane material;a second portion comprising: a mechanical assembly that interacts mechanically with the pump portion and valve portion of the flexible membrane material in such a manner as to achieve pumping of fluid along the fluid path; andan acoustic volume sensor to measure the change in fluid volume of the dispensing chamber, the acoustic volume sensor comprising: a structure containing a fixed-volume chamber, a first port, a measurement chamber, and the second port, wherein the structure is located within the apparatus so that the dispensing chamber and measurement chamber share a boundary defined by the a dispensing chamber portion of the flexible membrane material and the first port acoustically couples the fixed-volume chamber to the measurement chamber;a printed circuit board disposed within the structure, the printed circuit board including: a loudspeaker generating pressure waves in the fixed-volume chamber;a sensing microphone acoustically coupled to the measurement chamber via a second port, the sensing microphone producing a first signal based on the response of the measurement chamber to excitement by the loudspeaker, wherein the loudspeaker soundwaves pass through the first port, the measuring chamber and the second port before reaching the sensing microphone; anda reference microphone producing a second signal; anda processor configured to calculate a change in volume of the measurement region associated with a change in an acoustic characteristic of the measurement chamber, the processor determines a volume of fluid displaced from the dispensing chamber associated with the change in the volume of the measurement region. 11. The apparatus to dispense fluid according to claim 10 wherein the sensing microphone and loudspeaker are located to prevent the loudspeaker pressure waves from impacting the sensing microphone without passing through the measurement chamber. 12. The apparatus to dispense fluid according to claim 10 further comprising a flared aperture on at least one of the first and second ports, wherein the flared aperture is proximal to the measurement chamber. 13. The apparatus to dispense fluid according to claim 10 further comprising a dispensing spring, wherein the dispensing spring provides additional resilience to the dispensing chamber portion of the flexible membrane material. 14. The apparatus to dispense fluid according to claim 13 wherein the dispensing spring is part of the acoustic volume sensor. 15. The apparatus to dispense fluid according to claim 6, wherein the dispensing chamber portion of the flexible membrane material is a different material from one of the valve portion and the pump portion of the flexible membrane material.
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